Semiconductor crystals

“These crystals are analogous to organizing a table covered with scattered pencils into a pencil cup, ” said Yue “Jessica” Wang, a former UCLA doctoral student who now is a postdoctoral scholar at Stanford University and was the study’s first author. “The vertical orientation can save a great deal of space, and that can mean smaller, more efficient personal electronics in the near future.”

Once Kaner and his colleagues found they could guide the tetraaniline solution to grow vertical crystals, they developed a one-step method for growing highly ordered, vertically aligned crystals for a variety of organic semiconductors using the same graphene substrate.

“The key was deciphering the interactions between organic semiconductors and graphene in various solvent environments, ” Wang said. “Once we understood this complex mechanism, growing vertical organic crystals became simple.”

Kaner said the researchers also discovered another advantage of the graphene substrate.

“This technique enables us to pattern crystals wherever we want, ” he said. “You could make electronic devices from these semiconductor crystals and grow them precisely in intricate patterns required for the device you want, such as thin-film transistors or light-emitting diodes.”

The paper’s other authors were UCLA graduate students James Torres, Shan Jiang and Michael Yeung; Adam Stieg, associate director of shared resources at CNSI and the scientific director of the Nano and Pico Characterization Lab; Yves Rubin, UCLA professor of chemistry and biochemistry; and Xiangfeng Duan, UCLA professor of chemistry and biochemistry. Co-author Santanu Chaudhuri is a principal research scientist at the Illinois Applied Research Institute at University of Illinois at Urbana–Champaign.

RELATED VIDEO

RELATED FACTS

A device typically comprised of nanoscale semiconductor crystals used in combination with biological probes for a variety of applications.

Single crystals provide high mobility and outstanding electrical characteristics. Researchers in Dr. Zhenan Bao's lab at Stanford University have developed a simple technique for manufacturing large arrays of single-crystal transistors directly on wafers or...

Single crystals provide high mobility and outstanding electrical characteristics. Researchers in Dr. Zhenan Bao's lab at Stanford University have developed a simple technique for manufacturing large arrays of single-crystal transistors directly on wafers or...